NUTRIENT REMOVAL PROCESSES IN WASTEWATER TREATMENT We re Glad You re Here! Please, put your cell phones on vibrate during sessions and, take calls to the hallway
NUTRIENT REMOVAL PROCESSES IN WASTEWATER TREATMENT Presenters: Heath Edelman, PE Chris Hannum, PE 1.800.825.1372 www.entecheng.com
References Biological Nutrient Removal (BNR) Operation in Wastewater Treatment Plants. WEF Manual of Practice No. 29. Virginia: Water Environment Federation, 2005. Print. Gerardi, Michael. Nitrification and Denitrification in the Activated Sludge Process. New York: John Wiley and Sons, Inc., 2002. Print.
References Wastewater Engineering: Treatment and Disposal, 4 th Edition. Metcalf and Eddy, McGraw-Hill, 2003. Print.
SECTION 1 Wastewater Characteristics Pollution Concerns BNR Zones and Conditions Nitrogen Removal Phosphorus Removal
Section 1 Main Goals Identify the rational for nutrient limits including their pollution concerns Identify the zones and conditions required for nitrification, denitrification, and enhanced biological phosphorus removal
WW CHARACTERISTICS
Contaminants Low (mg/l) Medium (mg/l) Typical Domestic WW High (mg/l) TSS 120 210 400 BOD 110 190 350 Nitrogen (total as N) 20 40 70 Organic 8 15 25 Free Ammonia 12 25 45 Nitrites 0 0 0 Nitrates 0 0 0 Phosphorus (total as P) 4 7 12 Organic 1 2 4 Inorganic 3 5 10
Sources of Nitrogen Nitrogen is a naturally occurring element that is essential for growth and reproduction in all living organisms. Nitrogen is the most abundant compound in the atmosphere
Forms of Nitrogen Ammonia (NH 3 ) Ammonium ion (NH 4+ ) Organic Nitrogen Nitrite (NO 2- ) Nitrate (NO 3- ) Nitrogen Gas (N 2 )
Sources of Phosphorus Phosphorus is a key component in the process of energy metabolism by cells and the cell membrane Phosphorus is found in: Fertilizers Detergents / Cleaning Products Human / Animal Waste
Forms of Phosphorus Orthophosphates Phosphate ion (PO 3-4 ) Simplest form; available for biological Form that is precipitated; chemical removal 70% - 90% of TP Phosphoric Acid (H 3 PO 4 ) Dihydrogen Phosphate (H 2 PO 4- ) Hydrogenophosphate (HPO 2-4 ) Polyphosphates (condensed phosphates) Complex forms of inorganic orthophosphates
Forms of Phosphorus Organic Phosphates Soluble Biodegradable Non-Biodegradable (refractory) Particulate
POLLUTION CONCERNS
Nutrient Pollution Concerns DO Depletion Ammonia (Fish) Toxicity NH 3 Eutrophication; plant and algae growth Nitrate in Groundwater Methemoglobinemia Blue Baby Syndrome
Effluent Limits Approximately 25% of all water body impairments are due to nutrient-related causes (US EPA, 2007) Stringent effluent limits for Nitrogen and Phosphorus DEP; NPDES Basin Commissions; Docket
Chesapeake Bay Strategy Chesapeake Bay Strategy Existing WWTP not designed to limit nutrients Limit Total Nitrogen (TN) and Total Phosphorus (TP) discharges 0.4 MGD X 6.0 mg/l TN X 8.34 X 365 days = 7,306 # TN per year 0.4 MGD X 0.8 mg/l TP X 8.34 X 365 days = 974 # TP per year
Act 537 Planning Nutrient Credits Current cost of credits
BNR - Zones and Conditions
Biological Nutrient Removal (BNR) BNR (Biological Nutrient Removal) The biological removal of nitrogen and/or phosphorus through the use of microorganisms under different environmental conditions in the treatment process. (Metcalf and Eddy, 2003)
BNR Basic Design Considerations SRT: Solids inventory in reactor (MLSS) / Mass of MLSS wasted per day Stable population of nitrifiers HRT: Hydraulic allow time to react with pollutant Process parameters Organic loading rate F:M Aeration system capacity and layout
Biological Nutrient Removal (BNR) Aerobic Zone BOD removal Nitrification Phosphorous removal
BNR Basic Design Considerations Aerobic Zone Optimum Oxygen and Mixing Aerobic SRT for Nitrification MLSS Concentration HRT Temperature
Biological Nutrient Removal (BNR) Anoxic Zone Still has Oxygen Available in the form of NOx Conversion of nitrate (NO 3 -) to nitrogen gas (N 2 ) Denitrification Picture: www.suikime.com
Biological Nutrient Removal (BNR) Anaerobic Zone Production of VFA for growth of Bio-P bacteria Control of obligate aerobic filamentous bacteria Picture: www.suikime.com
BNR Basic Design Considerations Anoxic Zone Little to no D.O; <0.5 mg/l BOD: NO 3 -N Ratio (2.86 : 1) HRT (2.5 3.0 Hours) MLSS Recirculation Rate (1 4Q) Anaerobic Zone No D.O. and minimum nitrate HRT (1.0 1.5 Hours) BOD: P Ratio (30:1) MLSS Recirculation Rate (~2Q)
BNR Slug Loads / Recycle Sludge Thickening Digestion Anaerobic Aerobic Dewatering Filter backwash Septage Receiving
P from filtrate into reactor P from sludge into liquid SBR (anaerobic) SBR (aerobic) P from sludge back into liquid Digester P from liquid into sludge
NITROGEN REMOVAL
NITRIFICATION Two-step biological conversion The conversion of ammonium (NH 4+ ) to nitrite (NO 2- ), and finally to nitrate (NO 3- ) Nitrosomonas; rate limiting step Nitrobacter; max growth rate is higher Nitrification bacteria grow much slower than heterotrophic bacteria. Need longer hydraulic retention time Need longer solids retention time
NITRIFICATION NH 4+ + 1.5 O 2 NO 2- + H 2 O + 2 H + Oxygen Required = 3.43 lb / lb N Oxidized Alkalinity Required = 7.14 lb as CaCO 3 / lb N Oxidized NO 2- + 0.5 O 2 NO 3 - Oxygen Required = 1.14 lb / lb N Oxidized For Both Reactions Oxygen Required = 4.57 lb / lb N Oxidized Alkalinity Required = 7.14 lb as CaCO 3 / lb N Oxidized
NITRIFICATION As with BOD removal, nitrification can be accomplished in both suspended growth and attached growth processes: Suspended Growth (Activated Sludge) Single Sludge Nitrification Aeration Tank / Clarifier / Sludge Return System Two Sludge Nitrification Two aeration tanks and two clarifiers in series First Aeration tank = BOD Removal Second Aeration Tank = Nitrification Attached Growth BOD consumed first / then nitrification
Temperature Environmental Factors DO Concentration ph and Alkalinity Toxicity / Inhibition Sensitive Heavy metals Un-ionized ammonia
Single Sludge System
Two Sludge System
DENITRIFICATION The conversion of nitrate (NO 3- ) to nitrogen gas (N 2 ) Can use Oxygen, Nitrate, or Nitrite as their terminal electronic acceptor (oxygen source)
DENITRIFICATION NO 3 + Org. Carbon N 2 + CO 2 + OH + H 2 O CO 2 + OH HCO 3 NO 3 NO 2 NO N 2 O N 2 2.86 lbs oxygen recovered / lb NO 3 -N 3.57 lbs alkalinity recovered / lb NO 3 -N
DENITRIFICATION Carbon Augmentation Methanol Ethanol Acetic Acid Molasses Food processing organic waste (sugars) Soft drink wastes Engineered substances
PHOSPHORUS REMOVAL
Don t I Remove Phosphorus Now? Influent phosphorus = 4 mg/l to 12 mg/l Without phosphorus removal 5% to 10%: Primary Settling / Secondary Clarification 20% to 25%: Bacteria growth in Activated Sludge process 200 mg/l BOD removes 2 mg/l TP Final effluent: 3 mg/l to 4 mg/l TP
(Further) Phosphorus Removal Chemical Precipitation Iron Aluminum Calcium Enhanced Biological Phosphorus Removal (EBPR) Physical Filtration Membrane Technologies
Chemical Precipitation Phosphate concentration Effects of ph Dose Requirements
Iron Compounds Chemical Precipitation Ferric Chloride (FeCl 2 ); Most typical Ferrous Chloride (FeCl 3 ) Ferrous Sulfate (Fe(SO 4 )) Aluminum Compounds Aluminum Sulfate (Alum); Most typical Sodium Aluminate Polyaluminum Chloride Lime Addition
Chemical Precipitation Dosing Locations Polymer Polymer Influent Rapid Mix Primary Clarifier Aeration Basin Secondary Clarifier Filter Effluent Metal Salt Sludge Metal Salt Sludge Metal Salt Backwash
Sludge Increase - Chemical Precipitation 62 dry T/day Before Phosphorus Removal 353 wet T/day hauled 80 dry T/day 414 wet T/day hauled After Phosphorus Removal
Biological Phosphorus Removal Advantages Less sludge production compared to chemical precipitation More easily dewatered than Alum sludge Less chemical usage Disadvantages Dependability More Phosphorus release in sludge handling May require chemical backup
Enhanced Biological Phosphorus Removal (EBPR) Volatile fatty acid (VFA) production (anaerobically) Phosphorus release by bio-p bacteria (anaerobic conditions) Excess phosphorus uptake by bio-p bacteria
Phosphorous Release Anaerobic Zone Easily biodegradable organic matter (VFA) Accumulated organic substances (PHB & PHV) Energy Polyphosphate - (voluline) granule Bacteria schematic PO 3 4
Phosphorus Uptake Aerobic Zone CO 2 + H 2 O Accumulated organic substances (PHB & PHV) Energy Polyphosphate - (voluline) granule Bacteria schematic Cell contains 5 to 10% P PO 3 4
EBPR Treatment Processes Biological Alternatives (anaerobic zone) Modified Bardenpho Process (5-stage) SBR Process Operationally Modified Activated Sludge Process (i.e. oxidation ditch)
Physical Filtration 2 to 3% of organic solids is TP Effluent TSS of 20 mg/l = 0.4 to 0.6 mg/l TP Membrane Removes TP is TSS Removes dissolved TP
QUIZ ON SECTION 1 (10 min) And then Break (10 min)
BNR Processes SECTION 2
Section 2 Main Goals Identify the different treatment processes used to conduct Biological Nutrient Removal (BNR) Discuss design and process considerations for retrofitting systems or building new
BNR PROCESSES
BNR Process Configurations Although the exact configurations of each system differ, BNR systems designed to remove TN must have: Aerobic Zone for nitrification and ortho P uptake Anoxic Zone for denitrification BNR systems designed to remove TP must have: Anaerobic Zone (Anaerobic = No NOx Anoxic = No D.O.)
Inflow and Infiltration How well you control Inflow and Infiltration (I/I) can limit process modifications All wastewater systems are only as good as their biology Most BNR requires longer MCRT Regular wash outs cannot occur if BNR is to occur
Decision Making Data, data and more data ( more data = less construction costs) Synchronized influent and effluent (prior to disinfection) sampling - Composite as well as grabs -Ammonia, TKN, NO3 and NO2 -BOD (if you have to) -COD preferably -Phosphorus -Soluble and insoluble forms
BNR Process Configurations What is right for you? Target effluent limits Nutrient credits New Plant Of course more flexibility and options Retrofit of Existing Usually requires a balance of nutrient credits and some new construction
BNR Process Configurations What is right for you? Retrofit of Existing or Selecting New Aeration basin size and configuration Clarifier capacity Type of aeration system Sludge processing units Instrumentation Operator skills
BNR Process Configurations What is right for you? Aeration basin size and configuration Creating anoxic and anaerobic space Hydraulic grade through the system W/O new tanks you are borrowing from existing capacity (see sampling) Depth for aeration and transfer efficiency has to be a consideration Segregation fiberglass or concrete baffles Package system post segregation
BNR Process Configurations What is right for you? Clarifier capacity No specific need for a lower mass flux rate BNR sludges are anticipated to settle better Nitrification/Denitrification control requires the removal of sludge from the clarifier in a rapid fashion Direct suction clarifier or single sweep type can enhance the removal Package systems can present issues (air-lifts)
BNR Process Configurations What is right for you? Type of aeration system Gentle fine bubble diffusers avoids potential shearing D.O. control with VFD blower motor is a must for consistent reliability Basin geometry and segregation considerations D.O. trending is recommended
BNR Process Configurations What is right for you? Sludge processing units Accumulation of nutrients in the sludge Dewatering and supernatant can return high strength waste to the process Higher solubility that allows for accelerated uptake Low digester alkalinity can solubilize phosphorus Test your current filtrate and supernatant
BNR Process Configurations What is right for you? Operator skills Finer touch with your system In house sampling and knowledge takes on a larger role Data logging and understanding takes additional operator time Most new systems require an understanding of PLC and SCADA components
Suspended Growth Systems Wuhrmann Process Ludzack-Ettinger Process Modified Ludzack-Ettinger (MLE) Process Bardenpho Process (Four Stage) Bardenpho Process (Five Stage) Sequencing Batch Reactor (SBR) Oxidation Ditch Processes
Wuhrmann Process The Wuhrmann Process is a single sludge nitrification system with the addition of an unaerated anoxic reactor between the aerobic nitrifying reactor and the secondary clarifiers. This treatment system configuration places the denitrification reactor after the nitrification step. It should be noted that the lack of carbonaceous substrate available for denitrification in the anoxic tank significantly limits the denitrification rate. Influent Aerobic Tank (fully aerobic) Anoxic Tank Secondary Clarifier Effluent RAS Pump
Ludzack-Ettinger Process Initially developed to take advantage of the carbonaceous substrate available in the influent wastewater by placing the anoxic reactor upstream of the nitrification reactor. In this design, nitrates included in the RAS flow are mixed with influent wastewater and reduced to nitrogen gas in a pre-denitrification reactor upstream of the aeration basin. This process is limited in total nitrogen removal efficiency due to the quantity of nitrate recycled back to the anoxic zone in the RAS flow. Influent Anoxic Tank Aerobic Tank (fully aerobic) Secondary Clarifier Effluent RAS Pump
Modified Ludzack Ettinger (MLE) Process This process modifies the Ludzack-Ettinger process by adding a recirculation of mixed liquor recycle (MLR) from the end of the aeration tank to the beginning of the anoxic tank. Nitrified Recycle Influent Anoxic Tank Aerobic Tank (fully aerobic) Secondary Clarifier Effluent RAS Pump
MLE Process Monitoring Requirements Reactor Parameter Rationale Anoxic D.O. Reduce denitrification rate; will use O2. Aerobic Nitrate-N Mixed Liquor Recycle Alk., ph High nitrate recycled to aerobic zones may cause filamentous bulking. High D.O. may inhibit upstream denitrification. Low D.O. may inhibit nitrification. Nitrification consumes alkalinity.
Bardenpho (4 Stage) Process Incorporates the principles used for the MLE and Wuhrmann processes to create two anoxic zones to achieve a higher level of total nitrogen removal. The first two stages function similarly to the MLE process, although the anoxic zone is sometimes sized to accommodate at least 400% MLR rate. Nitrified Recycle Aeration Tank Influent Anoxic Tank Aerobic Tank (fully aerobic) Anoxic Tank Secondary Clarifier Effluent RAS Pump
Bardenpho (4 Stage) Process The primary anoxic zone removes the majority of the nitrate generated in the process. The secondary anoxic zone, located outside the MLE loop, provides denitrification for that portion of the flow that is not recycled to the primary anoxic zone. The fourth reactor zone in the process is an aerobic or reaeration reactor and serves to strip any nitrogen gas formed in the second anoxic zone. Nitrified Recycle Aeration Tank Influent Anoxic Tank Aerobic Tank (fully aerobic) Anoxic Tank Secondary Clarifier Effluent RAS Pump
Bardenpho (4 Stage) Process Reactor Configurations Plug Flow Oxidation Ditch In the U.S. we commonly use the Oxidation Ditch as the MLE portion of the process with separate complete mix reactors for the secondary anoxic and secondary aerobic zones.
Bardenpho (5 Stage) Process
Bardenpho (5 Stage) Process Fermentation Stage: Activated sludge is returned from the clarifier to the fermentation state. This sludge is contacted with the plant influent to produce the a stress condition that allows large quantities of phosphorus to be removed from the wastewater biologically in subsequent aerobic stages. Organism stress occurs in the absence of D.O. and NO 3.
Bardenpho (5 Stage) Process First Anoxic Stage: Mixed liquor containing nitrates from the third stage. Here it is mixed with conditioned sludge from the fermentation stage in the absence of oxygen. Bacteria utilized BOD in the influent, reducing the nitrates to gaseous nitrogen.
Bardenpho (5 Stage) Process Nitrification Stage: Oxygen is introduced in the nitrification stage to oxidize BOD and ammonia. Mixed liquor, containing nitrates, is recycled back to the first anoxic stage.
Bardenpho (5 Stage) Process Second Anoxic Stage: Nitrate, no recycle to the first anoxic stage, is introduced to the second anoxic stage where it is reduced (in the absence of oxygen) to nitrogen gas.
Bardenpho (5 Stage) Process Reaeration Stage: Utilized to ensure the biomass remains aerobic, thereby, ensuring that the sludge does not go septic and release phosphorus in the final clarifier.
Sequencing Batch Reactor (SBR) Variable volume suspended growth treatment technologies that uses time sequences to perform the various treatment operations that continuous treatment processes conduct in different tanks.
SBR Fill React Settle 33 % Vol. Disp. 6 - hour cycle Decant Idle Time
SBR Aerated Fill To remove BOD and to achieve simultaneous nitrification/denitrification Aerated & mixed Design time = 0% to 50% of fill time Design time is a function of BOD & TKN loads, BOD:P ratio, temperature & effluent requirement
SBR React To remove BOD, achieve nitrification, enhance phosphorous uptake, and to Denitrify with anoxic react for low effluent nitrate requirement Aerobic react (aeration & mixing) Anoxic react (mixing only) Design time = 25% to 40% of cycle time Design time is a function of BOD & TKN loads, temperature & effluent requirement
SBR Settle, Decant, and Idle To settle solids, withdraw clarified effluent, waste excess sludge, and remove nitrate in the sludge blanket Design settle time = 0.75 hrs. (fixed) Design decant time = 0.5 hrs. Design idle time = 0.25 hrs.
SBR Settle, Decant, and Idle To remove nitrate, promote VFA production & growth of Bio-P bacteria, and to control aerobic filamentous organisms. Static Fill Mixed Fill Design Time = 50% to 100% of Fill Time Design time is a function of BOD & TKN loads, BOD: P ratio, temperature & effluent requirements
SBR Cycle Time Distribution (6 hr cycle) Effluent Total Nitrogen < 10 mg/l Anoxic Fill Static+ Mixed Aerobic Fill React Aerobic Settle 0 Decant Idle 90 min 90 min 90 min 45 min 30 min 15 min Total Cycle Time = 360 minutes
SBR Cycle Time Distribution (6 hr cycle) Effluent Total Nitrogen < 5 mg/l Fill React Anoxic Fill Static+Mixed 60 min Air AF AXF AF AXF Air Off Settle Decant Idle On On 40 min 20 min 40 min 20 min 40 min Air Mix 20 min 30 min 45 min 30 min 15 min Total Cycle Time = 360 minutes AF = Aerated Fill AXF = Anoxic Fill Mixed
SBR Considerations Significant Headloss through the system (fill and decant take away from reaction time) Difficulty removing floatable from the SBR tanks High flow decant sometime warrants equalization before downstream processes or discharge.
SBR Considerations More reactor volume required for nitrification compared to a flow through system. Typically lower MLSS inventory Give the operator more flexibility during I/I events
Oxidation Ditch Influent Oxidation Ditch Return Sludge Effluent Secondary Clarifier
Oxidation Ditch Extended aeration process Complete mix closed loop reactors Various Basin Configurations Single Ditch / Dual Ditch Phased Isolation Ditch Vertical Loop Reactor (VLR) Can be used in a sequencing batch mode Allows the operator to protect solids inventory by segregating a ring from the flow and returning it to operation after the event
Oxidation Ditch - Aeration Can be provided with horizontal brush aerators, vertical shaft mechanical aerators that impart a horizontal liquid velocity, or diffused aeration with submersible mixers.
Hybrid Systems Integrated Fixed Film Activated Sludge Rotating Biological Contactor Submerged Biological Contactor Membrane Bioreactor
Hybrid Integrated Fixed Film Activated Sludge (IFAS) The IFAS processes include any wastewater treatment system that incorporates some type of fixed film media with a suspended growth activated sludge process.
Hybrid IFAS IFAS Media Varies greatly Ropes Looped strands Sponge cuboids Plastic wheels, or Packing material (Pictures Courtesy of Entex)
Hybrid IFAS Expand treatment capacity or upgrade the level of treatment by supplementing the biomass in a suspended growth activated sludge process by growing additional biomass on fixed-film media continued within the mixed liquor.
Advantages Hybrid IFAS Additional biomass for treatment without increasing solids loading on final clarifiers High rate treatment possible Improved settling characteristics Simultaneous nitrification and denitrification Improved resistance to toxic shock and washout. Makes tank reuse more feasible
Hybrid Rotating Biological Contactor (RBC) and Submerged Biological Contactor (SBC) Type of IFAS Consist of a series of circular disks mounted on a rotating horizontal shaft. This rotating shaft alternately exposing the disks to wastewater and air. Nitrification does not commence until CBOD is reduced sufficiently to allow nitrifiers to compete with heterotrophic bacterial on the media.
Not a common treatment method RBC Considerations Lower energy requirement Lower operational oversight Sizing and expandability can be and issue Past history with shaft failure has been mostly overcome through load monitoring
SBC Considerations Instead of rotating the media the flow is rotated via aeration around the media Potential for a turbid/pin floc in the effluent RAS contact to the effluent prior to final discharge Can allow for the reuse of existing basins and minimize any upgrade effort
Hybrid Membrane Bioreactor (MBR) Utilize membrane-type filtration units, instead of clarifiers, that are placed either directly in the activated sludge basin or are located outside the basin.
Hybrid Membrane Bioreactor Value over Conventional Processes Fewer process steps to achieve comparable effluent quality Eliminates filamentous sludge bulking issues. Low effluent turbidity Small footprint (MBR) Modular expansion capability Excellent nutrient removal capacity Reduced sludge yield
MBR Considerations Increased energy and pumping costs Higher quality effluent Redundant units needed for cleaning and service Allows for basin reuse Cost
Phosphorus Removal Phosphorus forms Ortho and Poly Anaerobic environment Fermentation and Acetate Production 0.5 to 1.0 hour HRT Conversion of Polyphosphate to Orthophosphate Orthophosphate taken up in an aerobic environment
QUIZ ON SECTION 2 (10 min) And then Break (10 min)
SECTION 3 Instrumentation Basics Troubleshooting Case Studies
Section 3 Main Goals Review basic instrument components Solve common troubleshooting scenarios Review of case studies
INSTRUMENTATION
Operation and Maintenance To achieve low TN and TP effluent concentrations, proper operation and control is essential Factors include: Temperature DO Levels ph Filamentous Growth etc
BNR Instrumentation Purpose Supplement the operators knowledge of the system Measure metrics that can be applied to decision making Automate decision making OPERATOR INPUT ON SETPOINTS IS CRITICAL
BNR Instrumentation Total Suspended Solids Meter Dissolved Oxygen Measurement ph Measurement Oxidation-Reduction Potential Ammonia and Ammonium Nitrate / Nitrite Phosphorus / Orthophosphate
SCADA Screen Dissolved Oxygen Trend Tank Volumes: Green, Yellow, Blue D.O. mg/l: Red, White, Purple
BNR Instrumentation D.O. monitoring has made the biggest impact ph and ORP are consistent and stable monitoring devices Other instruments are relatively new and continue to advance BNR system should incorporate SCADA into the overall control strategy
TROUBLE SHOOTING
Scenario 1 Nitrification Your extended aeration WWTP typically is excellent at both BOD and TKN removal but you recently notice that the BOD and TKN values have been slowly but steadily increasing. Is there more information that we need? What are some of the probable causes?
Scenario 2 Nitrification and Denitrification Your SBR WWTP is nitrifying (even better than normal) but your NO2+NO3-N is very high and the solids during clarification are rising. Is there more information that we need? What are some of the probable causes?
Scenario 3 Phosphorus Removal Your WWTP is typically producing TP effluent numbers below 0.8 mg/l but on April 9, 2013 the TP was 8 mg/l in the effluent. Is there more information that we need? What are some of the probable causes?
CASE STUDY
Existing Lititz Wastewater Treatment Plant
Lititz Wastewater Treatment Plant BNR Process Design Modeling (BioWin) Influent Anaerobic Pre Anoxic Aerobic 1st Aerobic IC Aerobic 2nd Post Anoxic Aeration Effluent WAS
TN (lbs) Lititz Wastewater Treatment Plant Upgrade BNR Process Operation Data 18,000 Monthly TN Discharge 16,000 14,000 12,000 10,000 8,000 6,000 4,000 2,000 0 Jun-08 Aug-08 Nov-08 Jan-09 Apr-09 Jul-09 Sep-09 Dec-09 Mar-10 May-10 Aug-10 Oct-10 Jan-11 Apr-11 Jun-11 Sep-11 Dec-11 Time
TN (lbs) Lititz Wastewater Treatment Plant Upgrade BNR Process Operation Data 200,000 180,000 160,000 TN Discharge Accumulation Discharge accumulation Annual cap load 140,000 120,000 100,000 80,000 60,000 40,000 20,000 0 Jun-08 Aug-08 Nov-08 Jan-09 Apr-09 Jul-09 Sep-09 Dec-09 Mar-10 May-10 Aug-10 Oct-10 Jan-11 Apr-11 Jun-11 Sep-11 Dec-11 Time
TP (lbs) Lititz Wastewater Treatment Plant Upgrade BNR Process Operation Data 1,600 Monthly TP Discharge 1,400 1,200 1,000 800 600 400 200 0 Jun-08 Aug-08 Nov-08 Jan-09 Apr-09 Jul-09 Sep-09 Dec-09 Mar-10 May-10 Aug-10 Oct-10 Jan-11 Apr-11 Jun-11 Sep-11 Dec-11 Time
TP (lbs) Lititz Wastewater Treatment Plant Upgrade BNR Process Operation Data 16,000 14,000 TP Discharge Accumulation Discharge accumulation Annual cap load 12,000 10,000 8,000 6,000 4,000 2,000 0 Jul-08 Oct-08 Jan-09 Mar-09 Jun-09 Sep-09 Nov-09 Feb-10 May-10 Jul-10 Oct-10 Dec-10 Mar-11 Jun-11 Aug-11 Nov-11 Time
Questions?
NUTRIENT REMOVAL PROCESSES IN WASTEWATER TREATMENT
Thank you QUIZ ON SECTION 3